Kiyoyoshi Nishita scite author profile

A cellulase [endo-b-1,4-D-glucanase (EC 3.2.1.4)] was isolated from the hepatopancreas of abalone Haliotis discus hannai by successive chromatographies on TOYOPEARL CM-650M, hydroxyapatite and Sephacryl S-200 HR. The molecular mass of the cellulase was estimated to be 66 000 Da by SDS/PAGE, thus the enzyme was named HdEG66. The hydrolytic activity of HdEG66 toward carboxymethylcellulose showed optimal temperature and pH at 38°C and 6.3, respectively. cDNAs encoding HdEG66 were amplified by the polymerase chain reaction from an abalone hepatopancreas cDNA library with primers synthesized on the basis of partial amino-acid sequences of HdEG66. By overlapping the nucleotide sequences of the cDNAs, a sequence of 1898 bp in total was determined. The coding region of 1785 bp located at nucleotide position 56-1840 gave an amino-acid sequence of 594 residues including the initiation methionine. The N-terminal region of 14 residues in the deduced sequence was regarded as the signal peptide as it was absent in HdEG66 protein and showed high similarity to the consensus sequence for signal peptides of eukaryote secretory proteins. Thus, matured HdEG66 was thought to consist of 579 residues. The C-terminal region of 453 residues in HdEG66, i.e. approximately the C-terminal three quarters of the protein, showed 42-44% identity to the catalytic domains of glycoside hydrolase family 9 (GHF9)-cellulases from arthropods and Thermomonospora fusca. While the N-terminal first quarter of HdEG66 showed 27% identity to the carbohydrate-binding module (CBM) of a Cellulomonas fimi cellulase, CenA. Thus, the HdEG66 was regarded as the GHF9-cellulase possessing a family II CBM in the N-terminal region. By genomic PCR using specific primers to the 3¢-terminal coding sequences of HdEG66-cDNA, a DNA of 2186 bp including three introns was amplified. This strongly suggests that the origin of HdEG66 is not from symbiotic bacteria but abalone itself.

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cDNA cloning of an alginate lyase from abalone, Haliotis discus hannai

Shimizu

Ojima

Nishita

2003

Carbohydrate Research

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Drastic Ca2+ sensitization of myofilament associated with a small structural change in troponin I in inherited restrictive cardiomyopathy

Yumoto

Morimoto

et al. 2005

Biochemical and Biophysical Research Communications

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cDNA cloning of myosin rod and the complete primary structure of myosin heavy chain of walleye pollack fast skeletal muscle

et al. 2000

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SUMMARY: The amino acid sequences of myosin rod containing subfragment‐2 (S2) and light meromyosin (LMM) were determined by cDNA cloning for walleye pollack fast skeletal myosin heavy chain. While S2 and LMM were composed of 442 and 656 amino acid residues, a total of 1937 amino acid residues accounted for the whole myosin heavy chain molecule with previously determined sequence for the subfragment‐1 heavy chain region of this fish. Both regions for S2 and LMM showed a seven‐residue repeat pattern characteristic to fibrous proteins with a coiled‐coil structure of two α‐helices, displaying a, b, c, d, e, f, and g where positions a and d were frequently occupied by hydrophobic amino acids and c and g often contained charged residues. The occurrence of a 28‐residue unit with repetitive sequence was also strongly suggested, when one and three skip residues were adopted into S2 and LMM, respectively. Thus, walleye pollack S2 and LMM consisted of 17 and 24 zones with a 28‐residue repeat rearrangement. There were several amino acid substitutions which might account for a low thermal stability of walleye pollack myosin heavy chain in comparison with the sequences of higher vertebrate counterparts. However, it seemed difficult to interpret such low stability only from the comparison in the 28‐residue repeat arrangement at the primary structure.

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Coordination structures of Ca²⁺ and Mg²⁺ in Akazara scallop troponin C in solution

Yumoto

Nara

Kagi

et al. 2001

European Journal of Biochemistry

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FTIR spectroscopy has been applied to study the coordination structures of Mg2+ and Ca2+ ions bound in Akazara scallop troponin C (TnC), which contains only a single Ca2+ binding site. The region of the COO– antisymmetric stretch provides information about the coordination modes of COO– groups to the metal ions: bidentate, unidentate, or pseudo‐bridging. Two bands were observed at 1584 and 1567 cm−1 in the apo state, whereas additional bands were observed at 1543 and 1601 cm−1 in the Ca2+‐bound and Mg2+‐bound states, respectively. The intensity of the band at 1567 cm−1 in the Mg2+‐bound state was identical to that in the apo state. Therefore, the side‐chain COO– group of Glu142 at the 12th position in the Ca2+‐binding site coordinates to Ca2+ in the bidentate mode but does not interact with Mg2+ directly. A slight upshift of COO– antisymmetric stretch due to Asp side‐chains was also observed upon Mg2+ and Ca2+ binding. This indicates that the COO– groups of Asp131 and Asp133 interact with both Ca2+ and Mg2+ in the pseudo‐bridging mode. Therefore, the present study directly demonstrated that the coordination structure of Mg2+ was different from that of Ca2+ in the Ca2+‐binding site. In contrast to vertebrate TnC, most of the secondary structures remained unchanged among apo, Mg2+‐bound and Ca2+‐bound states of Akazara scallop TnC, as spectral changes upon either Ca2+ or Mg2+ binding were very small in the infrared amide‐I′ region as well as in the CD spectra. Fluorescence spectroscopy indicated that the spectral changes upon Ca2+ binding were larger than that upon Mg2+ binding. Moreover, gel‐filtration experiments indicated that the molecular sizes of TnC had the order apo TnC > Mg2+‐bound TnC > Ca2+‐bound TnC. These results suggest that the tertiary structures are different in the Ca2+‐ and Mg2+‐bound states. The present study may provide direct evidence that the side‐chain COO– groups in the Ca2+‐binding site are directly involved in the functional on/off mechanism of the activation of Akazara scallop TnC.

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